Héloïse Muller

Genome evolution in yeasts

Identifying the mechanisms of eukaryotic genome evolution by comparative genomics is often complicated by the multiplicity of events that have taken place throughout the history of individual lineages, leaving only distorted and superimposed traces in the genome of each living organism. The hemiascomycete yeasts, with their compact genomes, similar lifestyle and distinct sexual and physiological properties, provide a unique opportunity to explore such mechanisms. We present here the complete, assembled genome sequences of four yeast species, selected to represent a broad evolutionary range within a single eukaryotic phylum, that after analysis proved to be molecularly as diverse as the entire phylum of chordates. A total of approximately 24,200 novel genes were identified, the translation products of which were classified together with Saccharomyces cerevisiae proteins into about 4,700 families, forming the basis for interspecific comparisons. Analysis of chromosome maps and genome redundancies reveal that the different yeast lineages have evolved through a marked interplay between several distinct molecular mechanisms, including tandem gene repeat formation, segmental duplication, a massive genome duplication and extensive gene loss.

Total Synthesis of a Functional Designer Eukaryotic Chromosome

Designer Chromosome One of the ultimate aims of synthetic biology is to build designer organisms from the ground up. Rapid advances in DNA synthesis has allowed the assembly of complete bacterial genomes. Eukaryotic organisms, with their generally much larger and more complex genomes, present an additional challenge to synthetic biologists. Annaluru et al. (p. 55, published online 27 March) designed a synthetic eukaryotic chromosome based on yeast chromosome III. The designer chromosome, shorn of destabilizing transfer RNA genes and transposons, is ∼14% smaller than its wild-type template and is fully functional with every gene tagged for easy removal. A synthetic version of yeast chromosome III with every gene tagged can substitute for the original. Rapid advances in DNA synthesis techniques have made it possible to engineer viruses, biochemical pathways and assemble bacterial genomes. Here, we report the synthesis of a functional 272,871–base pair designer eukaryotic chromosome, synIII, which is based on the 316,617–base pair native Saccharomyces cerevisiae chromosome III. Changes to synIII include TAG/TAA stop-codon replacements, deletion of subtelomeric regions, introns, transfer RNAs, transposons, and silent mating loci as well as insertion of loxPsym sites to enable genome scrambling. SynIII is functional in S. cerevisiae. Scrambling of the chromosome in a heterozygous diploid reveals a large increase in a-mater derivatives resulting from loss of the MATα allele on synIII. The complete design and synthesis of synIII establishes S. cerevisiae as the basis for designer eukaryotic genome biology.

Uneven Distribution of Mating Types among Genotypes of Candida glabrata Isolates from Clinical Samples

ABSTRACT In order to shed light on its basic biology, we initiated a population genetic analysis of Candida glabrata, an emerging pathogenic yeast with no sexual stage yet recognized. A worldwide collection of clinical strains was subjected to analysis using variable number of tandem repeats (VNTR) at nine loci. The clustering of strains obtained with this method was congruent with that obtained using sequence polymorphism of the NMT1 gene, a locus previously proposed for lineage assignment. Linkage disequilibrium supported the hypothesis of a mainly clonal reproduction. No heterozygous diploid genotype was found. Minimum-spanning tree analysis of VNTR data revealed clonal expansions and associated genotypic diversification. Mating type analysis revealed that 80% of the strains examined are MATa and 20% MATα and that the two alleles are not evenly distributed. The MATa genotype dominated within large clonal groups that contained only one or a few MATα types. In contrast, two groups were dominated by MATα strains. Our data are consistent with rare independent mating type switching events occurring preferentially from type a to α, although the alternative possibility of selection favoring type a isolates cannot be excluded.

Genomic polymorphism in the population of Candida glabrata: Gene copy-number variation and chromosomal translocations

The genomic sequence of the type strain of the opportunist human pathogen Candida glabrata (CBS138, ATCC 2001) is available since 2004. This allows the analysis of genomic structure of other strains by comparative genomic hybridization. We present here the molecular analysis of a collection of 183 C. glabrata strains isolated from patients hospitalized in France and around the world. We show that the mechanisms of microevolution within this asexual species include rare reciprocal chromosomal translocations and recombination within tandem arrays of repeated genes, and that these account for the frequent size heterogeneity between chromosomes across strains. Gene tandems often encode cell wall proteins suggesting a possible role in adaptation to the environment.

3D organization of synthetic and scrambled chromosomes

INTRODUCTION The overall organization of budding yeast chromosomes is driven and regulated by four factors: (i) the tethering and clustering of centromeres at the spindle pole body; (ii) the loose tethering of telomeres at the nuclear envelope, where they form small, dynamic clusters; (iii) a single nucleolus in which the ribosomal DNA (rDNA) cluster is sequestered from other chromosomes; and (iv) chromosomal arm lengths. Hi-C, a genomic derivative of the chromosome conformation capture approach, quantifies the proximity of all DNA segments present in the nuclei of a cell population, unveiling the average multiscale organization of chromosomes in the nuclear space. We exploited Hi-C to investigate the trajectories of synthetic chromosomes within the Saccharomyces cerevisiae nucleus and compare them with their native counterparts. RATIONALE The Sc2.0 genome design specifies strong conservation of gene content and arrangement with respect to the native chromosomal sequence. However, synthetic chromosomes incorporate thousands of designer changes, notably the removal of transfer RNA genes and repeated sequences such as transposons and subtelomeric repeats to enhance stability. They also carry loxPsym sites, allowing for inducible genome SCRaMbLE (synthetic chromosome rearrangement and modification by loxP-mediated evolution) aimed at accelerating genomic plasticity. Whether these changes affect chromosome organization, DNA metabolism, and fitness is a critical question for completion of the Sc2.0 project. To address these questions, we used Hi-C to characterize the organization of synthetic chromosomes. RESULTS Comparison of synthetic chromosomes with native counterparts revealed no substantial changes, showing that the redesigned sequences, and especially the removal of repeated sequences, had little or no effect on average chromosome trajectories. Sc2.0 synthetic chromosomes have Hi-C contact maps with much smoother contact patterns than those of native chromosomes, especially in subtelomeric regions. This improved “mappability” results directly from the removal of repeated elements all along the length of the synthetic chromosomes. These observations highlight a conceptual advance enabled by bottom-up chromosome synthesis, which allows refinement of experimental systems to make complex questions easier to address. Despite the overall similarity, differences were observed in two instances. First, deletion of the HML and HMR silent mating-type cassettes on chromosome III led to a loss of their specific interaction. Second, repositioning the large array of rDNA repeats nearer to the centromere cluster forced substantial genome-wide conformational changes—for instance, inserting the array in the middle of the small right arm of chromosome III split the arm into two noninteracting regions. The nucleolus structure was then trapped in the middle between small and large chromosome arms, imposing a physical barrier between them. In addition to describing the Sc2.0 chromosome organization, we also used Hi-C to identify chromosomal rearrangements resulting from SCRaMbLE experiments. Inducible recombination between the hundreds of loxPsym sites introduced into Sc2.0 chromosomes enables combinatorial rearrangements of the genome structure. Hi-C contact maps of two SCRaMbLE strains carrying synIII and synIXR chromosomes revealed a variety of cis events, including simple deletions, inversions, and duplications, as well as translocations, the latter event representing a class of trans SCRaMbLE rearrangements not previously observed. CONCLUSION This large data set is a resource that will be exploited in future studies exploring the power of the SCRaMbLE system. By investigating the trajectories of Sc2.0 chromosomes in the nuclear space, this work paves the way for future studies addressing the influence of genome-wide engineering approaches on essential features of living systems. Synthetic chromosome organization. (A) Hi-C contact maps of synII and native (wild-type, WT) chromosome II. Red arrowheads point to filtered bins (white vectors) that are only present in the native chromosome map. kb, kilobases. (B) Three-dimensional (3D) representations of Hi-C maps of strains carrying rDNA either on synXII or native chromosome III

Assembling large DNA segments in yeast.

As described in a different chapter in this volume, the uracil-specific excision reaction (USER) fusion method can be used to assemble multiple small DNA fragments (∼0.75-kb size) into larger 3-kb DNA segments both in vitro and in vivo (in Escherichia coli). However, in order to assemble an entire synthetic yeast genome (Sc2.0 project), we need to be able to assemble these 3-kb pieces into larger DNA segments or chromosome-sized fragments. This assembly into larger DNA segments is carried out in vivo, using homologous recombination in yeast. We have successfully used this approach to assemble a 40-kb chromosome piece in the yeast Saccharomyces cerevisiae. A lithium acetate (LiOAc) protocol using equimolar amount of overlapping smaller fragments was employed to transform yeast. In this chapter, we describe the assembly of 3-kb fragments with an overlap of one building block (∼750 base pairs) into a 40-kb DNA piece.

Cohesins and condensins orchestrate the 4D dynamics of yeast chromosomes during the cell cycle

Duplication and segregation of chromosomes involves dynamic reorganization of their internal structure by conserved architectural proteins, including the structural maintenance of chromosomes (SMC) complexes cohesin and condensin. Despite active investigation of the roles of these factors, a genome‐wide view of dynamic chromosome architecture at both small and large scale during cell division is still missing. Here, we report the first comprehensive 4D analysis of the higher‐order organization of the Saccharomyces cerevisiae genome throughout the cell cycle and investigate the roles of SMC complexes in controlling structural transitions. During replication, cohesion establishment promotes numerous long‐range intra‐chromosomal contacts and correlates with the individualization of chromosomes, which culminates at metaphase. In anaphase, mitotic chromosomes are abruptly reorganized depending on mechanical forces exerted by the mitotic spindle. Formation of a condensin‐dependent loop bridging the centromere cluster with the rDNA loci suggests that condensin‐mediated forces may also directly facilitate segregation. This work therefore comprehensively recapitulates cell cycle‐dependent chromosome dynamics in a unicellular eukaryote, but also unveils new features of chromosome structural reorganization during highly conserved stages of cell division.

Characterizing meiotic chromosomes' structure and pairing using a designer sequence optimized for Hi‐C

In chromosome conformation capture experiments (Hi‐C), the accuracy with which contacts are detected varies due to the uneven distribution of restriction sites along genomes. In addition, repeated sequences or homologous regions remain indistinguishable because of the ambiguities they introduce during the alignment of the sequencing reads. We addressed both limitations by designing and engineering 144 kb of a yeast chromosome with regularly spaced restriction sites (Syn‐HiC design). In the Syn‐HiC region, Hi‐C signal‐to‐noise ratio is enhanced and can be used to measure the shape of an unbiased distribution of contact frequencies, allowing to propose a robust definition of a Hi‐C experiment resolution. The redesigned region is also distinguishable from its native homologous counterpart in an otherwise isogenic diploid strain. As a proof of principle, we tracked homologous chromosomes during meiotic prophase in synchronized and pachytene‐arrested cells and captured important features of their spatial reorganization, such as chromatin restructuration into arrays of Rec8‐delimited loops, centromere declustering, individualization, and pairing. Overall, we illustrate the promises held by redesigning genomic regions to explore complex biological questions.

Choreography of budding yeast chromosomes during the cell cycle

To ensure the proper transmission of the genetic information, DNA molecules must be faithfully duplicated and segregated. These processes involve dynamic modifications of chromosomes internal structure to promote their individualization, as well as their global repositioning into daughter cells (Guacci et al., 1994; Kleckner et al., 2014; Mizuguchi et al., 2014). In eukaryotes, these events are regulated by conserved architectural proteins, such as structural maintenance of chromosomes (SMC i.e. cohesin and condensin) complexes (Aragon et al., 2013a; Uhlmann, 2016). Although the roles of these factors have been actively investigated, the genome-wide chromosomal architecture and dynamics both at small and large-scales during cell division remains elusive. Here we report a comprehensive Hi-C (Dekker et al., 2002; Lieberman-Aiden et al., 2009) analysis of the dynamic changes of chromosomes structure over the Saccharomyces cerevisiae cell cycle. We uncover specific SMC-dependent structural transitions between the different phases of the mitotic cycle. During replication, cohesion establishment promotes the increase of long-range intra-chromosomal contacts. This process correlates with the individualization of chromosomes, which culminates at metaphase. Mitotic chromosomes are then abruptly reorganized in anaphase by the mechanical forces exerted by the mitotic spindle on the centromere cluster. The formation of a condensin-dependent loop, that bridges centromere cluster with the cenproximal flanking region of the rDNA, suggests that these forces may directly facilitate nucleolus segregation. This work provides a comprehensive overview of chromosome dynamics during the cell cycle of a unicellular eukaryote that recapitulates and unveils new features of highly conserved stages of the cell division.

Redesigning chromosomes to optimize conformation capture (Hi-C) assays

In all chromosome conformation capture based experiments the accuracy with which contacts are detected varies considerably because of the uneven distribution of restriction sites along genomes. Here, we redesigned and reassembled in yeast a 145kb region with regularly spaced restriction sites for various enzymes. Thanks to this design, we enhanced the signal to noise ratio and improved the visibility of the entire region as well as our understanding of Hi-C data, while opening new perspectives to future studies.In all chromosome conformation capture based experiments the accuracy with which contacts are detected varies considerably because of the uneven distribution of restriction sites along genomes. Here, we redesigned and reassembled in yeast a 145kb region with regularly spaced restriction sites for various enzymes. Thanks to this design, we enhanced the signal to noise ratio and improved the visibility of the entire region as well as our understanding of Hi-C data, while opening new perspectives to future studies.In all chromosome conformation capture based experiments the accuracy with which contacts are detected varies considerably because of the uneven distribution of restriction sites along genomes. In addition, repeated sequences as well as homologous, large identical regions remain invisible to the assay because of the ambiguities they introduce during the alignment of the sequencing reads along the genome. As a result, the investigation of homologs during meiosis prophase through 3C studies has been limited. Here, we redesigned and reassembled in yeast a 145kb region with regularly spaced restriction sites for various enzymes. Thanks to this Syn-3C design, we enhanced the signal to noise ratio and improved the visibility of the entire region. We also improved our understanding of Hi-C data and definition of resolution. The redesigned sequence is now distinguishable from its native homologous counterpart in an isogenic diploid strain. As a proof of principle, we track the establishment of homolog pairing during meiotic prophase in a synchronized population. This provides new insights on the individualization and pairing of homologs, as well as on their internal restructuration into arrays of loops during meiosis prophase. Overall, we show the interest of redesigned genomic regions to explore complex biological questions otherwise difficult to address.